Electrical and spectroelectrochemical investigation of thiophene-based donor-acceptor copolymers with 3,4-ethylenedioxythiophene
Marcus Henrique de Araujo; Tulio Matencio; Claudio Luis Donnici; Hállen Daniel Rezende Calado
Abstract
Keywords
References
1 Mishra, A., Ma, C. Q., & Bauerle, P. (2009). Functional oligothiophenes: molecular design for multidimensional nanoarchitectures and their applications.
2 Perepichka, I. F., & Perepichka, D. F. (2009).
3 Vasilyeva, S. V., Beaujuge, P. M., Wang, S. J., Babiarz, J. E., Ballarotto, V. W., & Reynolds, J. R. (2011). Material strategies for black-to-transmissive window-type polymer electrochromic devices.
4 Beaujuge, P. M., & Reynolds, J. R. (2010). Color control in pi-conjugated organic polymers for use in electrochromic devices.
5 Zhao-yang, Z., Yi-jie, T., Xiao-qian, X., Yong-jiang, Z., Hai-feng, C., & Wen-wei, Z. (2012). Electrosynthesises and characterizations of copolymers based on thiophene and 3,4-ethylenedioxythiophene in boron trifluoride diethyl etherate.
6 Ming, S., Zhang, S., Liu, H., Zhao, Y., Mo, D., & Xu, J. (2015). Methacrylate modified polythiophene: electrochemistry and electrochromics.
7 Lee, J. U., Jung, J. W., Emrick, T., Russell, T. P., & Jo, W. H. (2010). Synthesis of C(60)-end capped P3HT and its application for high performance of P3HT/PCBM bulk heterojunction solar cells.
8 Hu, X. L., Zuo, L. J., Nan, Y. X., Helgesen, M., Hagemann, O., Bundgaard, E., Shi, M. M., Krebs, F. C., & Chen, H. Z. (2012). Fine tuning the HOMO energy levels of polythene 3,4-b thiophene derivatives by incorporation of thiophene-3,4-dicarboxylate moiety for photovoltaic applications.
9 Kim, H., Lee, H., Jeong, Y., Park, J. U., Seo, D., Heo, H., Lee, D., Ahn, Y., & Lee, Y. (2016). Donor acceptor polymers with a regioregularly incorporated thieno 3,4-b thiophene segment as a pi-bridge for organic photovoltaic devices.
10 Kim, J. H., & Park, J. G. (2015). Effect of donor weight in a P3HT:PCBM blended layer on the characteristics of a polymer photovoltaic cell.
11 Bora, C., Sarkar, C., Mohan, K. J., & Dolui, S. (2015). Polythiophene/graphene composite as a highly efficient platinum-free counter electrode in dye-sensitized solar cells.
12 Zhang, J., Li, X. X., Guo, W., Hreid, T., Hou, J. F., Su, H. Q., & Yuan, Z. B. (2011). Electropolymerization of a poly(3,4-ethylenedioxythiophene) and functionalized, multi-walled, carbon nanotubes counter electrode for dye-sensitized solar cells and characterization of its performance.
13 Vashchenko, A. A., Vitukhnovsky, A. G., Taidakov, I. V., Tananaev, P. N., Vasnev, V. A., Rodlovskaya, E. N., & Bychkovsky, D. N. (2014). Organic light-emitting devices with multi-shell quantum dots connected with polythiophene derivatives.
14 Qu, B., Feng, L. M., Yang, H. S., Gao, Z., Gao, C., Chen, Z. J., Xiao, L. X., & Gong, Q. H. (2012). Color-stable deep red-emitting OLEDs based on a soluble terpolyrner containing fluorene, thiophene and benzothiadiazole units.
15 Gupta, N., Grover, R., Mehta, D. S., & Saxena, K. (2016). A simple technique for the fabrication of zinc oxide-PEDOT:PSS nanocomposite thin film for OLED application.
16 Zhu, L. M., Shi, W., Zhao, R. R., Cao, Y. L., Ai, X. P., Lei, A. W., & Yang, H. X. (2013). n-Dopable polythiophenes as high capacity anode materials for all-organic Li-ion batteries.
17 Zhang, H. Q., Hu, L. W., Tu, J. G., & Jiao, S. Q. (2014). Electrochemically assembling of polythiophene film in ionic liquids (ILs) microemulsions and its application in an electrochemical capacitor.
18 Zhen, S., Ma, X., Lu, B., Ming, S., Lin, K., Zhao, L., Xu, J., & Zhou, W. (2014). Supercapacitor electrodes based on furan-EDOT copolymers via electropolymerization.
19 Ates, M., & Arican, F. (2015). Electrocoated films of poly(N-methylpyrrole-co-2,2 '-Bithitiophene-co-3-(Octylthiophene)), characterizations, and capacitor study.
20 Hu, F. Q., Xue, Y., Xu, J. K., & Lu, B. Y. (2019). PEDOT-based conducting polymer actuators.
21 Yuk, H., Lu, B. Y., & Zhao, X. H. (2019). Hydrogel bioelectronics.
22 Lu, B. Y., Yuk, H., Lin, S. T., Jian, N. N., Qu, K., Xu, J. K., & Zhao, X. H. (2019). Pure PEDOT:PSS hydrogels.
23 Dyer, A. L., Craig, M. R., Babiarz, J. E., Kiyak, K., & Reynolds, J. R. (2010). Orange and red to transmissive electrochromic polymers based on electron-rich dioxythiophenes.
24 Zhang, Z. Q., Liu, W. Q., Yan, J. L., Shi, M. M., & Chen, H. Z. (2016). A bipolar diketopyrrolopyrrole molecule end capped with thiophene-2,3-dicarboxylate used as both electron donor and acceptor for organic solar cells.
25 Chotsuwan, C., Asawapirom, U., Shimoi, Y., Akiyama, H., Ngamaroonchote, A., Jiemsakul, T., & Jiramitmongkon, K. (2017). Investigation of the electrochromic properties of tri-block polyaniline-polythiophene-polyaniline under visible light.
26 Capan, A., & Ozturk, T. (2014). Electrochromic properties of 3-arylthieno 3,2-b thiophenes.
27 Gora, M., Pluczyk, S., Zassowski, P., Krzywiec, W., Zagorska, M., Mieczkowski, J., Lapkowski, M., & Pron, A. (2016). EPR and UV-vis spectroelectrochemical studies of diketopyrrolopyrroles disubstituted with alkylated thiophenes.
28 Vogel, S., & Holze, R. (2005). Spectroelectrochernistry of intrinsically conducting aniline-thiophene copolymers.
29 Zagorska, M., Kulszewicz-Bajer, I., Pron, A., Sukiennik, J., Raimond, P., Kajzar, F., Attias, A. J., & Lapkowski, M. (1998). Preparation and spectroscopic and spectroelectrochemical characterization of copolymers of 3-alkylthiophenes and thiophene functionalized with an azo chromophore.
30 Alakhras, F. (2016). Spectroelectrochemistry of intrinsically conducting selenophene-3-chlorothiophene copolymers.
31 Yigitsoy, B., Varis, S., Tanyeli, C., Akhmedov, I. M., & Toppare, L. (2007). Electrochromic properties of a novel low band gap conductive copolymer.
32 Chen, J. H., Dai, C.-A., & Chiu, W.-Y. (2008). Synthesis of highly conductive EDOT copolymer films via oxidative chemical in situ polymerization.
33 Ates, M., & Ekmen, I. (2018). Capacitance behaviors of EDOT and pyrrole copolymer, and equivalent circuit model.
34 Kulandaivalu, S., Zainal, Z., & Sulaiman, Y. (2015). A new approach for electrodeposition of poly (3, 4-ethylenedioxythiophene)/polyaniline (PEDOT/PANI) copolymer.
35 Yijie, T., Kai, Z., Zhaoyang, Z., Haifeng, C., Chunlin, J., & Yulei, Z. (2016). Synthesis, characterizations, and electrochromic properties of donor-acceptor type polymers containing 2, 1, 3-benzothiadiazole and different thiophene donors.
36 Araujo, M. H., Matencio, T., Donnici, C. L., & Calado, H. D. R. (2016). Synthesis and electrochemical investigation of beta-substituted thiophene-based donor-acceptor copolymers with 3,4-ethylenedioxythiophene (EDOT).
37 Bechinger, C., Burdis, M. S., & Zhang, J. G. (1997). Comparison between electrochromic and photochromic coloration efficiency of tungsten oxide thin films.
38 Bobacka, J., Lewenstam, A., & Ivaska, A. (2000). Electrochemical impedance spectroscopy of oxidized poly(3,4-ethylenedioxythiophene) film electrodes in aqueous solutions.
39 Bard, A. J., & Faulkner, L. R. (2001).
40 Bonazzola, C., & Calvo, E. J. (1998). An electrochemical impedance and spectroelectrochemical study of the polypyrrole-flavin composite electrode.
41 Bredas, J. L., & Street, G. B. (1985). Polarons, bipolarons, and solitons in conducting polymers.
42 Spencer, H. J., Skabara, P. J., Giles, M., McCulloch, I., Coles, S. J., & Hursthouse, M. B. (2005). The first direct experimental comparison between the hugely contrasting properties of PEDOT and the all-sulfur analogue PEDOT by analogy with well-defined EDTT-EDOT copolymers.
43 Zhao, H., Tang, D. D., Zhao, J. S., Wang, M., & Dou, J. M. (2014). Two novel ambipolar donor-acceptor type electrochromic polymers with the realization of RGB (red-green-blue) display in one polymer.
44 Data, P., Zassowski, P., Lapkowski, M., Domagala, W., Krompiec, S., Flak, T., Penkala, M., Swist, A., Soloducho, J., & Danikiewicz, W. (2014). Electrochemical and spectroelectrochemical comparison of alternated monomers and their copolymers based on carbazole and thiophene derivatives.
45 Yigit, D., Udum, Y. A., Gullu, M., & Toppare, L. (2014). Electrochemical and spectroelectrochemical studies of poly(2,5-di-2,3-dihydrothieno 3,4-b 1,4 dioxin-5-ylthienyl) derivatives bearing azobenzene, coumarine and fluorescein dyes: effect of chromophore groups on electrochromic properties.
46 Wang, Z., Xu, J. K., Lu, B. Y., Zhang, S. M., Qin, L. Q., Mo, D. Z., & Zhen, S. J. (2014). Poly(thieno[3,4-
47 Lu, B. Y., Zhen, S. J., Zhang, S. M., Xu, J. K., & Zhao, G. Q. (2014). Highly stable hybrid selenophene-3,4-ethylenedioxythiophene as electrically conducting and electrochromic polymers.
48 Ming, S. L., Zhen, S. J., Liu, X. M., Lin, K. W., Liu, H. T., Zhao, Y., Lu, B. Y., & Xu, J. K. (2015). Chalcogenodiazolo [3,4-c]pyridine based donor-acceptor-donor polymers for green and nearinfrared electrochromics.
49 Ming, S. L., Zhen, S. J., Lin, K. W., Zhao, L., Xu, J. K., & Lu, B. Y. (2015). Thiadiazolo[3,4-c]pyridine as an acceptor toward fast-switching green donor-acceptor-type electrochromic polymer with low bandgap.
50 Gu, H., Ming, S. L., Lin, K. W., Chen, S., Liu, X. M., Lu, B. Y., & Xu, J. K. (2018). Isoindigo as an electron-deficient unit for high-performance polymeric electrochromics.
51 Vorotyntsev, M. A., Deslouis, C., Musiani, M. M., Tribollet, B., & Aoki, K. (1999). Transport across an electroactive polymer film in contact with media allowing both ionic and electronic interfacial exchange.
52 Pajkossy, T., & Kolb, D. M. (2007). Double layer capacitance of the platinum group metals in the double layer region.
53 Pajkossy, T., & Kolb, D. M. (2001). Double layer capacitance of Pt(111) single crystal electrodes.